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Inorganic Chemistry Bonding and Coordination Chemistry Books to follow Inorganic Chemistry by Shriver & Atkins Department of Chemistry Bonding in s,p,d systems: Molecular orbitals of diatomics, d-orbital splitting in crystal field (Oh, Td). Oxidation reduction: Metal Oxidation states, redox potential, diagrammatic presentation of potential data. Chemistry of Metals: Coordination compounds (Ligands & Chelate effect), Metal carbonyls – preparation stability and application. Wilkinson’s catalyst – alkene hydrogenation Hemoglobin, myoglobin & oxygen transport Environmental aspects of NOx, CO and CO2 Chemical Bonding • Two existing theories, • Valence Bond Theory (VBT) • Molecular Orbital Theory (MOT) Valance Bond Theory In valance bond theory, the wave function of an electron pair is formed by superimposing the wave functions for the separated fragments of the molecule. Linus Carl Pauling (1901-1994) Nobel prizes: 1954, 1962 Hybrid orbitals are formed in VB theory when a distribution of electron density needs to be modeled by using atomic orbitals on a given atom. The Central Themes of VB Theory Basic Principle A covalent bond forms when the orbtials of two atoms overlap and are occupied by a pair of electrons that have the highest probability of being located between the nuclei. Themes A set of overlapping orbitals has a maximum of two electrons that must have opposite spins. The greater the orbital overlap, the stronger (more stable) the bond. The valence atomic orbitals in a molecule are different from those in isolated atoms. Molecular potential energy curve shows the variation of the molecular energy with internuclear separation. Figure 11.1 Orbital overlap and spin pairing in three diatomic molecules Hydrogen, H2 Hydrogen fluoride, HF Fluorine, F2 Molecular Orbital Theory MOT: We can write the following principles Describe each electron in a molecule by a certain wave function - Molecular Orbital (MO). Each is defined by certain quantum numbers, which govern its energy and its shape. Each is associated with a definite energy value. Each electron has a spin, ± ½ and labeled by its spin quantum number ms. When building the molecule- Aufbau Principle (Building Principle) - Pauli Exclusion Principle. Linear combination of atomic orbitals Rules for linear combination 1. Atomic orbitals must be roughly of the same energy. 2. The orbital must overlap one another as much as possibleatoms must be close enough for effective overlap. 3. In order to produce bonding and antibonding Mos, either the symmetry of two atomic orbital must remain unchanged when rotated about the internuclear line or both atomic orbitals must change symmetry in identical manner. Rules for the use of MOs * When two AOs mix, two MOs will be produced * Each orbital can have a total of two electrons (Pauli principle) * Lowest energy orbitals are filled first (Aufbau principle) * Unpaired electrons have parallel spin (Hund’s rule) Bond order = ½ (bonding electrons – antibonding electrons) Linear Combination of Atomic Orbitals (LCAO) The wavefunctions of molecular orbitals can be approximated by taking linear combinations of atomic orbitals. A A AB = N(cA A + cBB) B B 2AB = (cA2 A2 + 2cAcB A B + cB2 B 2) Overlap integral +. +. . cA = cB = 1 g g = N [A + B] Amplitudes of wave functions added + . bonding A second MO can be obtained via subtraction of two AOs node +. -. cA = +1, cB = -1 u = N [A - B] . u . antibonding Nodal plane perpendicular to the H-H bond axis (en density = 0) Energy of the en in this orbital is higher. Amplitudes of wave functions subtracted. When 2 atomic orbitals combine there are 2 resultant orbitals orbitals.. Eg.. s orbitals Eg s*1s E high energy antibonding orbital 1sb 1sa s1s Molecular orbitals low energy bonding orbital Homonuclear Diatomics • MOs may be classified according to: (i) Their symmetry around the molecular axis. (ii) Their bonding and antibonding character. (iii) The atomic orbitals into which they separate at large internuclear distances. • s1s s1s* s2s s2s* s2p y(2p) = z(2p) y*(2p) z*(2p)s2p*. First period diatomic molecules Second period diatomic molecules Simplified Simplified MO diagram for B2 B B B2 3su* 1g* (px,py) 2p 2p LUMO 3sg 1u HOMO 2su* 2s 2s 2sg I = h - KE = 21.1 eV - KE eh UV photon ejected photoelectron N N N N ionized molecule UV-PES spectrum of N2 Heteronuclear Diatomics Similar to homonuclear diatomic molecules, the only difference is that the energy level diagram is not symmetrical. The bonding MOs are closer to the atomic orbitals which are lower in energy. The antibonding MOs are closer to those higher in energy. Summary From a basis set of N atomic orbitals, N molecular orbitals are constructed. In Period 2, N=8. The eight orbitals can be classified by symmetry into two sets: 4 s and 4 orbitals. The four orbitals from one doubly degenerate pair of bonding orbitals and one doubly degenerate pair of antibonding orbitals. The four s orbitals span a range of energies, one being strongly bonding and another strongly antibonding, with the remaining two s orbitals lying between these extremes. To establish the actual location of the energy levels, it is necessary to us absorption spectroscopy or photoelectron spectroscopy.